Method of and apparatus for analyzing gases



C. W. HEATH. METHOD 0F AND APPARATUS FOR ANALYZING- GASES.

APPLICATION FILED IULY 22. T918.

Patented. June 8, 1920.

"lul

Ill/l llll. YllllIlll/l. 'lIIlIllIIlIlII/IIII UNITED- STAT CHARLES W. HEATH,

OFFICE.

OF CINCINNATI, OHIO.

METHOD 0F AND APPARATUS FORjANALYZING GASES.

Application filed July 22,

To allwhom it may concern: 1 .I

Be it known that I, CHARLES W. HEATH, a citizen of the United States, and a resident of Cincinnati, in the county of Hamilton andState of Ohio, have invented certaln new and useful Improvements in Methods lof and Apparatus for Analyzing Gases, of

which the following is a specification.

My invention relates to means for making successive analysesof gases. Its object is to insure greater accuracy and to simplify the construction and operation of the apparatus, as well as'to render 1t more eiicient andreliable, less subject to derangement and requiring lesslabor and expense for construction, installation and maintenance.

Inthe drawing: Figure 1 is a vertical sectional dlagrammatic 'view' of apparatus embodying my 1nfvention Fig. 2 1s a partial similar view showing modification and Fig. 3 is a partial similar view showing another modification. As illustrated herein, the device is especially adapted for making frequent records of the percentage lofwcarbon .dioxid inthe gases leaving a urnace; although lit will be understood that theI apparatus may be adapted for` analyzing gases -other than furnace body of suitable liquid 5'.v This liquid may,

gases.

.As shown herein, a supply pipe 1,l leads directly from the 'flue or other inclosure 2,v

in which are found the gases to be analyzed This pipe 1 terminates 1n a trap 3 where it has a downwardly extending end part 4 a suitable distance below the surface of a be water. The induction vpipe 6 has an upper endjpart 7 within the'trap 3, extending I above thesurface of the liquid 5.. As'he're shown, the part 4 of'the supply pipe4 1 passes down through the top, and the in- `tom of t e casing of thetrap3. It wi1'l be.

duction ipe 6 passes out throughthe liotf understood that `'air-tight connections are made between the respective pipes and the top `and bottomV where theythus pass through. y The trap or seal-3 thus acts as a i check valvel in the pipe line constituted by the lpipes 1 and 6. 'A ny ordinaryv =check valve will serve this purpose',V The induceA tion pipe 6-continues'-downward fora considerable distance, preferably considerably Speceation of Letters Patent.

Patented Julie 8, 1920. 191s. seria1No.24s,259.

greater than is shown in the drawing, but

which is indicated by omitting part of the length of the induction pipe in the lower part of the drawing. At its lower end, this induction pipe 6 leads into the side of an ejector caslng 8, which at its top is closed to the atmosphere, and which has leading from 'its bottom the discharge pipe 9.

This pipe v9 which .is relatively narrow and preferably curved, as shown,` to insure `-capillarity therein for proper working of Y the siphon'is in practice somewhat longer than is shown onthe drawing, this being lindicated by omitting partof the length of this leg 12 as with the showing of the induction pipe 6. The upper bend 13 of the Siphon 11 is a considerable distance below the trap 3,'and the shorter leg 14 communicates withthe interiorv of a tall, narrow stand-pipe or tank 15 very close to the bottom thereof. pipe 16 leading from any suitable .source `of 'constant supply discharges water into this stand-pipe 15.y For I clearness, this supply of-water lis indicated in thel drawing asleaving the pipe -16.in the l form ofi, distinct drops,..although a Small continuous stream is generally used. y.

-The apparatus so farnde'scribed is adapted for. drawing, bythe intermittent action of thehsiphon, 11, successive charges or blasts of gases from the'iinclosure2 through -the supply pipe. into the-induction pipe 6, from which pipe the 'gases-are unable to pass back through vthe trapI or check valvet3.' v'AI-"he,

action will loe-intermittent, because it is induced by 4the ,discharge of the ySiphon 11 in the" .ejector casing 8; the passage of the water from the lower end of the long Siphon y leg 12 past the mouth of the induction pipe 6` in the ejector casing 8 creating the reduced pressure :in-the induction pipe 6,

which results a flow'l of the gases fromv the "inclosure 2 .tothe supply pipe 1 from.

which they bubble vupvthrongh the liquid 5 in the trap 3 and enter the induction .pipe 6.4 The action of the siphon 11 is intermittent because there can be no flow of. Water from the long leg 12 until the Water in the stand-pipe 15 has risen to the level of the upper bend 13 of the Siphon, asindicated by the heavy broken line in Figs. 1 and`2 of the drawing. When the Water does 'rise this high and become unbalanced, it

passes out rapidly through the leg 12, and the ysupply from the pipe 16 being slovver than this outward passage, the stand-plpe f 15 is soon emptied down to its outlet into `icient to note that there Will be successive charges or blasts or gases, eachV one of which will begin to be drawn through the supply pipe 1 into the induction pipe 6 as soon as the Siphon begins to discharge, and which Will cease to be drawn thereinto as sopn as lthe vSiphon ceases to discharge. t all -other times, there will `be no appreciable passage of the gases into the supply pipe 1 from the inclosure-2. I

It. Will thus be seen that means is provided forsegregating successive roughly defined quantities of the gases from the' inclo' sure 2 and cutting them olf therefrom in the induction pipe 6'. Of course, While'the ejector thus constituted bythe discharging Siphon is in operation, there is a current of these gases through theinduction pipe and out With the Water from the Siphon through the discharge pipe 9. V. But when the Siphon ceases to operate, there will, as*l is readily understood, be a body of the gases left'in the induction pipe 6 Which will be under at'- mospheric pressure, because. the lower end of the induction pipe is open directly to the atmosphere through the pipe 9 at the bottom of the ejector casing 8.A

The purpose of this is to supply, for accurate measurement and chemical treatment by the part of the apparatus hereinafter to be described, a body of the gases which` will be under atmospheric pressurey at the termination ofthe accurate measuring operation,

' so as to insure that every charge of gases,

' all accurately measured as to volume, ,will

` also all have the same pressure. Thus only is it possible to analyze;- and record the' analyses of equal masses Qf the gases at the successive analyses. Of course,`the temperatures of the successive 'accurately measured charges also influence this result; but it has been found possible to insure ypractically uniform temperature of the successive accurately measured charges. An exemple of means for this purpose is disclosed and claimed in my Patent No. 1,124,432, issued January 12,I 19,15, as are also various other details useful in preventing dilution or adulteration of the gases or' of the reagents used 1n the analyses.

It will be understood that anyiother details involved in analysis apparatus of this vgeneral type may be used in conjunction With my present improvement, which deals peculiarly With the control of the supply and the ultimate pressure of the gases to be analyzed, and by eliminating all ultimate intervention of valves, traps, bags or other means between they preliminary charge and the atmosphere, avoids the disturbing inacting requirements.

-Of Fig. 1.

It is in the relation to this group of details as "a whole to the induction pipe, that the modification'of Fig. 2 differs from the The pressure of example of Fig. 1. Thus, in the example of F ig., 1, the connecting pipe 17 leads from the induction pipe 6; Whereas in Fig. 2, the connectingpipe 17 leads from the supply pipe 1 corresponding to the supply pipe '1 of F ig. 1.,'4 and lthe induction 'pipe has no Aopening between the trap or check valve 3 and its lower end Where it opens into the ejector casing 8. With lthese explanations, it will be understood that the Siphon 11 and its accessories are thesame in either example, as may also be the details of the measuring and chemically-treating part of theap-l paratus vvhich "will lbe supplied through\the pipe.1 7"of Fig. 2, orthrough the pipe17 It will be 'Seen 'that finihisexampie 0f Fig. 2, the completion of the measurement 'of the charge is to be made-inconnection With a remaining body'of gases'A in the supply pipe 1; Whereas -this Acompletion is .to

be made in the example of Fig. 1 in connection with a remainingbodyin theinducl,

tion pipe 6. In the latter I ca"s' e,""tl'1e pressure will be' atmospheric;l in the vformer, it" Will v be Whatever is the pressure 'at that time inv ...the melosure 2 yand communicating' spaces, and which 4pressure-,1n some installations is v`very variable, as influenced'bythe wind over the top of the chimney and other variable i the influences well understood by those 'familiar with the art of furnace construction and management.

It will be seen, therefore, that the example of Fig. 1 is preferable; although the use ofthe example of Fig. 2 may afford accurate results where av practically uniform pressure in the inclosure 2 may be expected. In either case there`is no intervention of valves, traps, bags or the like at the termination of the accurate measuring operation as in the prior apparatus, as hereinbefore alluded to.

lVith most analyzing apparatus, and espelci'ally with that of the type herein exemplified, the actual period during which the apparatus is taking gas to be analyzed isl only about one-fourth of the total cycle of an, analysis. Prior devices employ a. constant flow or circulation of the gases past analysis apparatus. Therefore, for about three-fourths of the time, the gases are flowing through the communicating pipe to no practical advantage.

Now these gases being the products of combustion, carry with them large proportions of fine ash, dust and soot which are deposited in the communicating pipe. Where this flow or circulation is constant or continuous, the deposit in any given time will naturally be about four times as much as when the flow of the gases through the pipe is during only about one-fourth of the `total time. By providing apparatus which draws these gases through the communicating pipe only for about the time when the supply is needed, the deposit of solid substances is thus reduced to about one-fourth of the usual deposit. The result is that the communicating pipe may be made of about one-fourth of the cross-sectional area. An advantage attends this -in the economy of installation, since a pipe of only about half the diameter need be used andthe pipe and its fittings are very much less expensive and the` labor of installing them very much less.

In addition to this, the minimization of the total amount of 'gases that must pass through the communicating pipe reduces the frequency with which this pipe must be cleared out,.because of the great reduction of opportunity for deposit of the foreign matters in the pipe. 4 i

lVith this understandingI of the new conditions vrreatedjby my improvement'for the operationof an ing, and 4analyzing apparatus, the example of such apparatus herem given and which is "of the type which I y prefer, lmay nowy be briefly. described.

The-connecting 'pipe 17'oflig 1', or, as

" willbe understood, the connectingl pipe 17 ofjFig. 2, if this modification be employed, receives the gases at an upper end communisuitable volume determinwith the first measuring vessel- 18 preferablyv in the narrow neck 19 thereof situated between its relatively large lower part 20 and its relatively'l's'mall upperchamber 21. .A water inlet and outlet -pipe 22 leads' from the side of the, stand-pipe 15 into the interior of the lower part 20 of the first measuring-.vessel 18 and extends down near the bottom of the vessel. v

A tube 23 leads from the top of the upper chamber 21 A of the first measuring vessel well above the level of the upper bend 13 of the siphon 11, and then over and down close to the bottom of the second measuring Vessel 24 which it enters through the top thereof. Also extending in through thetop of the Vessel 24 is the residue discharge tube 25, which also leads above the level of the bend 13 of the siphon 11 and over and down into the interior of the stand-pipe 15 in the lower part thereof. r1 he vessel 24 is nearly filled with an absorbent liquid 26, which, for analyzing furnace gases, may be a solution of caustic potash. The stem 27 projects down from the float chamber 28 through the top of the vessel 24 with its lower end projecting a suitable distance down into this liquid. rIfhe float chamber 28 has the relatively wide and high neck. 29 in which a float 30 may move freely up and down, and which float has extending up from it a light rod 31 passing through a guide 32. and carrying suitable record-making means 33 to coact with a chart 34 made to revolve at a constant rate, so that the relative height of the' float 30 'at different times may be recorded'son this-chart 34. The details of this recording mechanism, not forming part of 110 the present invention, need not be further described or illustrated herein.

The first measuring vessel 18, with its connections, respectively, to the stand-pipe- 15 and th'e second measuring or absorption 115 or other constituent, the proportion of l which is to be determined by an elimination and subtraction process,and 'so controlling the escape-'of the residual gases that rise above v4the liquid 26 in the vessel 24, that these gases, by their pressure on the liquid 25 the adjacent parts of the .tubes 23 and 25.

v 26, cause it to rise through the :27 into the float chamber 28 and push the float .30:

residual gases. The more of the constituent that was `absorbed from the or1g1nal,i/ gas,

- the less willithe recording means be r lsed and with the chart properly graduated, thd

percentagelof the Varsorbed constituent will be directly indicated on the chart.

lThis pumping action` in the present ex- =ample is caused by the periodic rising and pi v15. lipposing the Water.i n the stand-` Vfalling of the bodyof Waterl the standpipe 15 has reached the `level of the /upper '-bend. 13 in the Siphon 11 and the discharge of the siphon and the ejectorl action begins, inducinga flow of gases into the vicinity of* the inlet of the pipe 17 or 17, .as the casef may be, the water in the stand-pipe -now y thev atmospheric pressure in the induction balls rapidly. In fillingthe stand-pipe' to that height, it has, of course, by its Sicomf pipe 1 Where .the apparatus is connected l munication through the pipe 22 and vessel 18, risen in the pipe 17 or 1 7 and also in As the Water falls in the stand-'pipe 15, it Will fall in the connecting pipe171or 17 and the gases will rush in throughthis pipe, 4under theI pressure in `the pipe 6 or l', and follow the Water down in the pipe v17' or 17 When the Water has fallen below the level of the entrance of the pipe`17 or 17 to the neck-19, these gases enter the first measuringves'sel 18 and this intakeof the gases will continue untilthe Water has fallen to a l'levelwhere it will no longer flow out` 15 fallsbelow the ventrance of the tube 25v the tu e 25.

l provement.

I l through the pipe-22. Also. during this ,op-j

eration, the water will have been vfalling inl the `discharge tube 25 d the residual gasesv from the 'previous anflljfsis in thevessel 24' above the li uid 26 will follow this'falling 1, a' material intake of gases after the e'ectorA Water, and W en the Waterin the stand-pipe therein, these residual gases will be partly discharged tothe atmosphere throu h. the

open top of the standfpipe 15;'th1s disL-' charge bei-ng facilitated by the pressure due to the liquid 26 regaining itsv lower-level from where it has been held up in the float chamber, 28 by these residual gases as long as the -were confined by th Water risen in Another action takes place during this eriod which is especially important as making clear the principle of the present im- The liquid k26 in thevessel 24, o'f course, acts as a seal or rcheck-valve, so that no gases can flow backl into the tube 23 from the vessel'24. As the final l amount of gas is `'discharged from the measuring chambenl; the water 20 from the stand-pipe 15 -enters a short distance .up vinto tlnisfitube 23. 'As

the water fallstherein, there is no supply of gaseous substance to maintain 4the pressure abovev the Water, the only pressure being that of the'negligible quantity of gases that There will, therefore,.be a partial vacuum in the tube 23 during the fallin .of the Waterin the stand-pipe 15 until t e Water remained in this tube 23 at the last analysis. i

fallsbelovvl the entrance of the connecting pipe 17 or 17 which vacuum will then,'of l.

`11. But-owing to this ejector action, the' tendency of the gases to pass into the pipev v'17 or 17 even with the partial vacuum pre' vailing in, the first measuringvessl- 18,. is

action ceases andlthere again prevails either pipe 6 or the normal pressure in the supply -v which thel Water stops overfiowin vfrom the lnotj as great as it will be when theaejector first measuring vessel 18 throng the Vpipe 22 as the water `in the stand-pipe passes below this pipe 22, is, in the example of Fig.

v1, considerably higher than it will ultimately be vwhen vthe lejector action .ceases and the atmospheric pressure is free to act on the surface of the liquidremaininginv the vessel 18 `and press the liquid'down therein and up v inside the tube 22 for the surplus to. lim/'v over into the now practically empty `standpipe 15.v The pressurel in the stand-pipe 15 is, of course, atmospheric, and the action willbe simply a balancing one during' whichv the level of thewater inthe vessel 18 falls suiiiciently` to cause, in the example of Fig.l

action has ceased. It is thus insure that the final intake will be under -the influence ofthe pressure of the source from which' it was desired to take the gases, undisturbed by any impelling action, Whether this pres-l sure be atmospheric as it will b'e yWith the. inlet from-the induction pipe 6, or the pres-4 -sure of ythe space 2 if directly from lthe 'suphus, whatever may have been the pressure prevailing w'hilej thev first measuring vess'l 18 was receiving gasesfrom a -body of gases under the action of the ejector, the

v ultimate pressure Will be this' pressure of the-gases in a quiescent state.

Therefore, with the'stand-pip'e nofw grad-z ually`. filling again and overfiowing through lao ,the pipe 6 or the pipe 1*',

of the upper chamber 21 of tlie'vessel 18 with the source of supply lwill be cut off` when the water passes'the lower end of the pipe 17 or 17 in the neck 19 of the vessel 18. It will be seen that lthe roughly defined volume of gaseous mixture has become substantially quiescent and the atmospheric or other dependable pressure set up in this" volume of gas. after the ejector action had ceased, will now lon'g since have been well established, and it will be this pressure at which the definitely and accurately meas-A ured volume will be cut offv in the upper chamber 21.

,'It is, therefore, notlessentialthat there" should be any material intake of gases to 'the measuring chamber 21 after the ejector stops, although degree. Y

The water continuing to rise, will push this always occurs msome Asubstantially all of this laccurately measfor segregating a roughly defined quantity "of the gases from which the accurate charge is to be taken and determined at the next rising of the water, which quantity has become substantiallyA quiescent under conditions created between the ceasing of the vejector action and this accurate determination.

Where these gases are taken from the induction pipe 6 after having passed through the trap 3, so that the atmospheric pressure is controlling, the cross-section of the induction pipe may be increased, as shown in Fig.

1, becausel it increases the relative volume` of gases in the induction pipe below the entrance to the conducting pipe 17 tov such an extent that should there be a considerable volume of back-flow through the induction,v

pipe, due to atmospheric pressure through the ejector-casing 8, as during the change of liquid levelin the vessel 18 after the ejector -action has stopped, the entrance of air to the measurmgchamber 18 will be prevented.`

It maybe said, however, that ordinarily the induction pipe 6 will have sufficientv volume to insure this, since it should be carried down for a considerable distance along with the long leg 12 of the siphon, because the force of discharge of the Siphon depends largely on the length of this leg 12.

As hereinbefore alluded to, considera-ble as the case may be, l

modification in the details of the measuring and absorption and recording parts ofthe,y

apparatus may be made in accordance with requlrements peculiar .to these; but it will be understood that any apparatus of this type and operating periodically according to the broad principle ofthis type of apparatus, may have its operation greatly improved and its construction and maintenance greatly simplified by the embodiment there- 1n of my present invention. The advantages' are especially realized in the example of Fig. 1- -vwhere atmospheric pressurel at theultij Iin ate volume-determining instant in the 'op eration of the measuring device ris insured at every analysis.

In .'thef modification of Fig. 3, the first measuring vessel 18a has its upper part connected directly with the interior of the" stand-pipe 15 by a short pipe 22a, and a bell I 35 depends from the neck 19. with its lower rim. well below the pipe 22a. The water in the vessel- 18a, never falling below where -it will run out through the pipe 22a, will thus always submerge the lower rim of the bell 35 and at all times form a liquid seal between the space inside the bell 35, lwhich communicates through the neck 19 with the upper part 21 of the vessel 18a, and the-space 36 outside the bell 35 within the vessel'l8,

.which communicateswith the stand-pipe 15 through the pipe 22a.

As here shown, a flexible bag 37 is fastened around the lower part of the bell- 35 so that two liquid spaces are defined, the one inside the bag 37 containing water which will not materially affect'the gases, and the s ace outside .receiving the water which ows in and out from the stand-pipe 15 in the manner hereinbefore described.. 4This inflow and outflow ofthis water will cause the water in the fiexible bag` 37 to rise`and fall past the mouth, of the connecting pipe 178. for forcing the gases .into the second measuring chamber and through the tube 23.

The bag 37 need not be used except in localities where the water is strongly alkaline or otherwise active upon the gases th t are to be analyzed. But when the bag 37 v not `used, the bell 35 may simply takewthel place of the tube' 22 extending close to the bbttom of the vessel -18 in Fig. 1. This allows the pipe 22a to be short and straight; and the lower part 38 of the vessel 18a may 'be detachable from the upper part, as by beingv threaded therein, as shown. This makes it convenient to equip the device with the bag 37 whenever this is found necessary, without disturbing any of the numerous connections.

to the upper part of the vessel 18". 'l A Where the bell 35 is used, it is preferable to have the, discharge tube 25a e'nter the space 36, and to lead another discharge tube 39 from this space into the stand-pipe 15 at tlieiproper` height, in place of the tube 25 mixture, which comprises drawing a roughly leading directly into the stand-pipe 15, as in Fig. 1. This avoids the trapping of air or gases in the space 36 at each rise of the mixture, which comprises exposing said mixwater.

@therwise it will be understood that the devicewith these modifications of Fig. 3, may be constructed as fully shown in lFig. 1, and the connecting pipe-17SL ma be connected either as the pipe 17 in ig. 1, or

as the pipe 17 .in Fig. 2, and thus used in v conjunction with the ejector. and Siphon, as hereinbe'fore fully described in connection with either example. The principle of op; eration of thel bag 37 when used, is similar to that of the device disclosed and claimed.

inI my Patent No. 1,121,244, dated December 15, 1914, and it will be understood that other detailsl of that patent may be found useful in connection with the present invention. Also, my Patent No. 1,119,956, dated December 8, 1914, disclosing and claiming analysis apparatus with more especial relation to the recording means, in-vcludes details in conjunction with which the present invention may be readily used. In fact, any analysis apparatus of the general type therein exemplified may be improved by the incorporation therein of the present invention. fore possible, and while certain constructional details are deemed preferable in connection with my invention, and I have shown and described these rather specificall in elucidating the construction and use oiY my invention, as is required, I do not wish to be understood as being limited to such precise showing and description, buthaving thus fully described my invention, what I claim as new and desire to secure by Letters Patent is:

1. The method of analyzing a gaseous defined quantity of said mixture and withdrawing from this quantity, while it is being thus drawn, a volume of said mixture but leaving said volume connected with said quantity, then leaving said roughly defined quantity substantially quiescent, then cutting ofi' some of the volume Withdrawn,

whereby the pressure of the volume, thus cut off, is substantially that of this quiescent quantity of'mixture, and then analyzing said cut olf volume of mixture.

2. The method of analyzing a gaseous mixture, which comprises drawing a roughly defined quantity of` said'mix'ture in an in-" closure open to the atmospherefand lwithdrawing from this quantity, while it is being thus drawn, avolumeof said`mixture but leaving said volume connected with said quantitythen leaving' said quantity ofthe mixture substantially quiescent and at sub-I stantially atmospheric pressure, then cutting off some of the volume withdrawn, whereby Many modifications are therewhereby said drawn quantit" tially quiescent vwhen said vo ume is deter-.

the pressure of the volume, thus cut oit, is substantially atmospheric, and then analyzing saidcut oil'l volume of mixture.

3. `The method of analyzing a gaseous mixtureis withdrawn under the influence of said inlet end of said siphon, then stopping said siphon and thereby leaving said quantity of the mixture substantially quiescent, then cutting of some of' said volume, whereby the pressure of the volume, thus cut off, is substantially that of this quiescent quantity" of mixture, and then analyzing said volume of mixture thus cutoff.

- 4. The method of analyzing a gaseous mixture which comprises exposing said mixture to the Iinfluence of both the inlet and discharge ends of an operating Siphon, in a suitable inclosure open to the atmosphere, whereby a roughly defined quantity of said mixture is segregated under theiniiuence of -said discharge end of said siphon and a volume of said mixture is withdrawn under stantially quiescent and at substantially atmospheric pressure, then cutting 'oii some o'fsaidvolume, whereby the pressure of the volume, thus cutohis substantially. atmospheric, and then analyzing said volume 'of l mixture thus cut off..

5. In gas-analysis apparatus, determining means for determining and dellvering to analyzing. means a volume 'of gaseous mixture to be analyzed, means for drawing a roughly defined quantity of gaseous mixture, means for admitting a volume of said quantity to said determining means while said quantity is beingY drawnbut leaving said volume connected with said quantity, means for cutting off the admitted volume of mixture in said determining means land thereby determining the volume of said mixture to be analyzed, and means for terminating the drawing o eration on said` mixture before said vo ume is cut ofi",

is substanmined, and whereby the.. pressure of the determined yolume is substantiallyfthat of this 'quiescent quantity of mixture.

, 6. In gas-analysis apparatus, determining means for determlning and delivering to an- Afalyzing means a volume of gaseous mixture to be analyzed, means for-drawing aroughly -vdefined quantity of gaseous mixture and retaining some of said quan'tityof mixture in commu-mcatlon with the atmosphere, means for admitting a volume of said retained quantity of mixture to said determining means while the mixture is being thus drawn and exposed to the atmosphere, but leaving said volume connected with said quantity, means for cutting ofi' fthe ad mitted volume of mixture in said determining means, whereby a volume of said mixture is determined in said determiningl means, and means for terminating the drawing operation on said quantity of mixture before said volume is cut off, and thereby leaving said drawin quantity of mixture substantially quiescent at the determination of said volume, whereby the pressure of the Adetermined volume is substantiallyY the atmospheric pressure of this substantially quiescent quantity-of mixture.

7 In gas-analysis apparatus, the combination of a main gas pipe-line, means for causingv an intermittent iow of av 4gaseous mixture 'through said main pipe-line, a gasmeasuring vessel,u a branch of said main' pipe-line vcommunicating with said vessel, yand means for transferring from said main pipe-line through said branch into ,said vessel, and measuring in said vessel, suc-- cessive charges of said gaseous mixture to be delivered from said vessel for analysis.

8. In gas-analysis apparatus, the com- .bination of a main gas pipe-line, an intermittently operating gas ejector, means whereby said ejector causes an intermittent flow of a gaseous mixture through Isaid* mainpipe-line, a gas-measuring vessel, and

.means -for transferring, during the time of gas lowin said main pipe-line, 'successive charges f said gaseous mixture from said. pipe-line to said vessel and measuring said charges to be'delivered from said vessel for analysis.

9. In gas-analysis apparatus, the bination of a main gas pipe-line, means fof' causing an intermittent flow of a gaseous mixture through said main pipe-line, means in. said main pipe-line for permitting said intermittent flow but for preventing flow in the opposite direction, a gas-measuring vessel communicating with said main pipe-j line, and means for transferring from said main pipeline to said vessel, and measuring in said vess`el,successive charges of said gaseous mixture -to beV delivered from said vessel for analysis.

10.- In 1gas-analysis apparatus, the combination of a main gas-pipe-line, means for causing an intermittent ilo'w ofia gaseous mixture through, said ,main pipe-line, means in said main pipe-line'for permitting said intermittent flow. butv for. preventing 'low` in the opposite directionya gas-measuring vessel, and means for i,ransferring, during the time of gas flow in jsaid'm-ain pipe line,

successive charges of vsaid gaseous mixture from said pipe line to saidgvesseland measuring said charges to` be delivered from said vessel for analysis.

11. In gas-analysis apparatus, the :combination of a main gas pipe-line, an ejector, means"J for intermittently operatingl said ejector to intermittently draw a gaseous y ;,mixture through said main pipe-line, means in said main pipe-line to permit said gaseous mixture to be drawn through said main pipe-line but to prevent flow in the opposite direction, Aa gas-measuring" vessel in communication with said main pipe-line between said means for/preventing backlow and said ejector,e means for transferring successive charges of gas from said main pipe-line to said measuring vessel while said gaseous mixture is being drawn through said main pipe-line, means whereby said successive charges are accurately measured vas to lyolume, and means whereby said ejector is inoperative at the time of accurate measurement and affords freeI sive charges of gas from said main pipe-line to said measuring vessel while said gaseous inixture isbeing drawn through said main `-pipe-line, means wherebyl said successive charges areaccurately measured as to volume, and means whereby said ejector is inoperative at thetime of.- accurate meas:- urement and affords free 4communication through said main pipe-line between the in I terio'r of said vesseland the atmosphere.l

13. In gashanalysis apparatus, the combi# nation of a1 main gas pipe-line, an' interini't-i tently operatingsiphon, aliquid supply for' said Siphon, an ejector intermittentlyI o er-l ated by' the discharge from said sip on to intermittently draw a` gaseous mixture throughsaid main pipe-line, meansin said main pipe-line to permit said gaseous-mixture to bedrawh ltherethrough but to=pre vent flow of saidmixture in the oppositedirection, a gas-measuring ,vessel communicating with said main pipe-line between said means for preventing back-flowand said ejector, means forl transferring from said main pipe-lmeto said measuring Avessel sucf cessive charges of gasy while said 'gaseous Inixtureis being drawn through said main vpipe-line, means whereby successive charges of said vmixture are accurately measured as to volume, and means whereby said siphon and ejector are inoperative at the time of measurement whereby the pressure of said charges is equalized with the pressure of the atmosphere in communication with the intey rior-of said measuring vessel through said ture to be drawn therethrou h but to pre-l.

vent flow of said mixture int e opposite direction, a `ras-measuring vessel communicating with said main pipe-line between said.

means for preventing back-How and said ejector, means for transferring Afrom said main pipe lien to said 4measuring vessel suc-E.

' cessive charges of gas while said gaseous mixture is being drawn through said main pipe-line, means whereby successive charges of said mixture are accurately measured as to volume, and means whereby said #Siphon and eejctor are inoperative at the time'of measurement whereby Athe.. p1:essure of said charges is equalized with the pressure of the atmosphere in communication with the interior of said measuring vessel through said comprising a siphon whereby saidl pump is ejector and said main pipe line.

15. In gas-analysis apparatus, a gas, pump intermittently operated, an ejector receiving the discharge of and thereby intermittently operated by said Siphon, a suppl pipe leading from'the ultimate source o- `supply of l the mixture `that is-to be analyzed,.'an induc- 'tion` pipe communicating withA said ejector,

means permitting lowof said mixture from said; supply pipe into said induction pipe underthe action of'said ejector; but preventing back-flow of said mixture from said .in- Y duction pipe into said supply pipe, one off the aforesaid pipes being'lconi'i'eeted with said gas pump, said Siphon operating said pump to take in .mixture from said one of said aforesaidpipes whilelthe siphon is dis-y charging and operating said ejector and said .ejector is-causigfl'ow of said mixture intosaid one of the aforesaid pipes, and said pump comprising means for maintaining' communication between said one of the aforesaid lpipes and said lpump until said siphon ceases to discha'irge, and thereafter cutting off said communication, whereby a definite volume of said mixture 'is delivered `pressure of the mixture-in lsaid one of the aforesaid pipes after said mixturehas-.be-y

lcome substantially quiescent therein.`

j 16. In gas-analysis apparatus,y 'a gasfpiimp comprising a Siphon wherebysaid pump is intermittently operated, an ejector receiving the discharge-of and thereby intermittently operated by said siphon, a supply pipe leading from the yultimate source f supply of the mixture that is to be-analyzed, aninduction pipe communicating with said ejector and open to the atmosphere therethrough, means permitting flow of said mixture from lsaid supply pipe intosaid induction pipe under the action of said ejector, but preventing back-flow of said mixture from said induction pipe into said supply pipe, said induction pipe being connected'with said gas pump, saidsipl'ion operating said pump to take in mixture from said induction pipe while the siphon is discharging and operating lsaid ejector and thereby causing How of saidmixtui'einto said induction-pipe, and

saidpump comprising means for maintaining communication between said induction pipe and said pump until saidsiphon ceases to discharge,- ai'id thereafter cutting oil' said communication, whereby a j deiinite volume of said mixture is delivered by said pump to analyzingmeans at the substantially-atmospheric pressure of the mixture in said inducy tion pipe after said mixture'has become substantially quiescent therein.'- j

17. Infgas-analysis apparatus, a supply pipe4 leading from the` ultimate source of supply-of mixture, aninduction pipe, means permitting iiow of mixture from said supply pipe 1into said induction" pipe but prevent-A ing back-flow of' mixture from said induction pipe to said supply pipe, a gas pum-p comprising a measuring vessel, l one of lthe'` aforesaid pipes being in communication with said measuringI vessel, a stand-pipe',meansto supply liquid to said stand-pipe, means -for con ucting. liquid between said stand-5 pipe and said measuring vessel, "a sip'ho'n ioo periodically discharging liquid frein4 said Lstand-pipe, whereb rises andfalls in said measuring vessellpast wherel said vessel com- -inun-icates with ysaid one lofsaid aforesaidI pipes, gas-conducting-` means between' said measuring vessel and saidanalyzing meansy. l

and iin-ejector communicating with said inthe liquid alternately stand-pipe and in said.

duction pipe and receiving the discharge of said -siphon, wherebyV lsaid `ejector induces a flow of said mixture vinto said one'of. the aforesaid pipes that i's incommunication with said measuringvessel-during the fall of liquid 4in said stand-pipe and measuring vessel, so that some of said mixture is then drawn into said measuring vessel, fand so that lwhen said liquid rises in "said .standpipe and measuring vesselv the operation -of said siphonand conse uent operation ofthe ejector has ceased be ore said liquid rises,` past where said measuringjvessel coininiini-I cates withsaid onel of the'aforesaidpipes,

and 4 whereby said' liquid thus. delivers a isq apparatus at substantiallyA `the' pressure o said mixture that is-then in a substantially quiescent state in said one of said aforesaid pipes.

18. pipe leading from the ultimate' source of supply of mixture, an induction-pipe, means permittingl flow of mixture from said supply pipe into said induction pipe but preventing back-flow of 'mixture from said induction pipe to `said supply pipe, a gas pump comprising a measuring vessel, said indu@- ltien pipe being in communication with said measuring vessel, a stand-pipe, means to supply liquid to said stand-pipe, means for conducting liquid between said stand-pipe and said measuring vessel, a Siphon periodically discharging liquid-:from said standpipe, whereby the liquid alternately rises and :falls in said stand-pipe and in saidmeasuring vessel past where said vessel communicates with said induction pipe, gas-A conducting means between said measuring vessel and said analyzing means,and an ejector receiving the discharge of said Siphon, said induction pipe communicating with Isaid ejector and opening to the atmos phere therethrough, whereby said ejectorv induces a flow, o f said mixture into said induction pipe during the fall of liquid in said stand-pipe and measuring vessel,` so that @some of said mixture is then drawn into said measuring vessel, and so that when said liquid rises in said stand-pipe and measuring vessel, the operation of said siphon and consequent operation of said ejector hasceased before said liquid rises past'where said measuring chamber communicates with said induction pipe, and whereby said liquid thus delivers a definite volume of said mixture to analyzing apparatus at substantially the atmospheric pressure of said'mixture that is then in a substantially quiescent stateinsaid inductionpipe.

'19. In apparatus for gas analysis, the combination of a main gas ipe line, means for 'causing intermittent ow of gaseous mixture in said main gas pipe line, and a gas pump adapted to draw successive charges orl for causing intermittent flow of gaseous -mixture in saidmain gas pipe line, a gas pump adapted to draw successive charges of'l gases from said -main pipe line, means In gas-analysisapparatus, a' supply whereby said pump discharges said charges of gases for analysis, means in' said main pipe line for permitting the flow of gases in one direction and for preventing the flow of gases in the opposite'direction, and means for opening up a .free communication between the interior of said gas pump and the atmosphere, at a time in the operation of the apparatus vwhen said charges of gases are about to be discharged for analysis,l whereby the pressure of each ofsaid charges of gases to beanalyzed is substantially equalized with the pressure of the atmosphere.'

21. In gas-analysis apparatus, means to supply gas mixture to analyzing means comprising a Siphon and an ejector receiving and operated by the discharge of 'said siphon, and means to eliminate the effect of capillarity of a subnormal discharge of said Siphon through said ejector.

22. A Siphon-operated ejector, and means to eliminate the effect of capilla-rity of a sub causing intermittency of thesiphon opera-'- tion, and means for eliminating the effect of capillarity in the outlet of said ejector between the siphon operations.

26. ln' gas-analysis apparatus, means to supply gas mixture to analyzing means comprising a siphonand an ejector receiving and operated by the discharge of said Siphon, and means to eliminate the effect of capillarity of a subnormal discharge of said siphon through saidejector consisting of an extended s rface adjacent to the final outlet orifice, alon whichA drops of liquid may travel away from said orifice.

27. A Siphon-operated ejector, and means to eliminate the effect of capillarity of a subnormal discharge of said siphon through said ejector consisting of an extended surface adjacent to the final outlet orifice, along which drops of liquid may travel away fromsaid orifice.

28. A Siphon-operated ejector, means for causing intermittency of the siphon operation, and means for eliminating the effect of capillarity in the outlet 'of sald ejector between the Siphon operations, consisting of an extended surface adjacent to the yfinal outlet orifice, along which drops of liquid may travel away from said orifice.

CHARLES W. HEATH. Witnesses:

CLARENCE PERDEW, IRENE PARKER. 

